ES2770756T3 - Double-sided push button with touch function - Google Patents

Abstract

Pushbutton (1), comprising a first switching contact (2) and a second switching contact (3), which are arranged spaced apart and in parallel with each other, the first switching contact ( 2) to approach the second switch contact (3) with application of force until it touches it and establish a power line connection with the second switch contact (3), the pushbutton (1) comprising a third switch contact (4 ), which is arranged spaced from the second switch contact (3) and in parallel on a side opposite the first switch contact (2), characterized in that the third switch contact (4) is configured to approach the second contact switch (3) with application of force until it touches it and establish a power line connection with the second switch contact (3), and the pushbutton (1) comprises an evaluation unit (6), which is with figured to operate the first (2) and / or the third switching contact (4) additionally as a capacitive or inductive touch sensor.

Description

DESCRIPTION

Double-sided push button with touch function

The invention relates to a pushbutton, comprising a first switch contact and a second switch contact, which are arranged spaced apart and in parallel with each other, the first switch contact being configured to establish a connection power line with force application with the second switching contact.

Push buttons are control elements that are used in a variety of electronic devices such as mobile phones, computer keyboards, and control panels.

Conventional push buttons are mechanical devices that are controlled by the application of force. They have a stable starting state, as well as a metastable state, implementing the transition from the starting state to the metastable state by applying mechanical force to the first switching contact. If no force acts on the first switching contact, the pushbutton is in the initial state. In this, the first and second switching contacts are spaced from one another. When the button is actuated, these are brought into contact, in the metastable state, and a power line connection is established. If the application of force to the first switching contact ends, the pushbutton switches independently to the starting state and the electrical connection is separated. The pushbuttons according to the state of the art are embodied, for example, as push-disc pushbuttons, membrane keys or spring keys. A push button according to the preamble of claim 1 comes from US2015 / 0097038A1.

Another possibility of implementing a pushbutton is to make it according to a capacitive or inductive principle. Capacitive pushbuttons according to the state of the art do not have mechanically movable components. They consist of two electrodes arranged spaced and parallel to each other, which are supplied with an auxiliary voltage and have an electrical capacity. The electrodes are applied to supports such as glass or foil and scanned with an evaluation unit. When the capacitive pulser carrier is touched, the capacity changes. This change is recorded by the evaluation unit. Inductive pushbuttons use active input elements that generate a magnetic field. In the conductive components of the pushbutton, an electric current is induced by it, which is recorded by the evaluation unit.

Conventional mechanical pushbuttons have the disadvantage that, particularly when used in mobile electronic devices, operating errors can occur, since they are often exposed to mechanical influences. Additional shields or protective covers to prevent this increase the amount of space required by the appliance, which is often not desired.

Capacitive or inductive pushbuttons include the disadvantage that they are only functional when supplied with an auxiliary voltage. In an application in mobile electronic devices, this leads to a considerably reduced service life, especially in the case of limited battery capacities. Furthermore, this type of pushbutton is also susceptible to operating errors due to unintentional touches.

Furthermore, the pushbuttons according to the state of the art have the disadvantage that they represent control elements, which only have a single input possibility. They can only provide simple information that says the push button is pressed at some point, or not. Thus, the application possibilities of the pushbuttons according to the state of the art in modern electronic devices are very limited, with a comparatively high demand for space.

It is the object of the invention to form a pushbutton that overcomes the disadvantages listed above.

According to the invention, the present object is achieved in that the pushbutton comprises a third switching contact, which is arranged spaced apart from the second switching contact and in parallel on a side opposite the first switching contact, the third contact being configured for establishing a power line connection with application of force to the second switching contact, and the pushbutton comprising an evaluation unit which is configured to operate the first and / or third switching contact additionally as a capacitive touch sensor or inductive.

The configuration according to the invention of the pushbutton offers the advantage that it leads to a pushbutton having a much greater number of input possibilities compared to pushbuttons according to the state of the art. The first and third switching contacts can be designed conductively or non-conductively outward, for example under a flexible foil, so that a key is formed. Thus, in a button according to the invention instead of a single input possibility (the button is pressed straight or not pressed) additional input possibilities can be implemented. These are broken down as follows:

- pressure on the first switching contact

- pressure on the third switching contact

- touch of the first switching contact

- touch of the third switching contact

In this regard, it is particularly advantageous that a combination of the input possibilities mentioned above can be used to generate combined input methods, such as, for example, a simultaneous pressure on the first and third switching contacts, or a simultaneous contact of the first and of the third switching contact. Consequently, compared to the pushbuttons according to the state of the art, the pushbutton according to the invention offers the advantage that it represents a control element which, with the same space requirement, encompasses much wider possibilities of use.

Another advantage is that the pushbutton according to the invention does not have to be supplied continuously with an auxiliary voltage, but that this can only be activated by pressing the first or third switching contact, or simultaneously on the first switching contact. switching and the third switching contact. In this way, it is achieved that the button according to the invention does not have a constant energy consumption, thereby extending the useful life of the mobile devices in which it is used. Furthermore, a possible handling error is avoided or at least the probability of a handling error is reduced.

Due to a variable configuration of the surface of the second switching contact, different distances can be implemented between the first switching contact and the second switching contact, as well as between the third switching contact and the second switching contact. In this way, the haptic feedback can be designed differently in the control of the first switching contact and the third switching contact.

The switch contacts of the pushbutton according to the invention can be implemented using, for example, foils with integrated conductive elements, metal foils, FP, PCBA, etc. In this way, the advantage is obtained that the pushbutton according to the invention can have a very low overall height, making it particularly suitable for use on thin plastic cards such as smart cards, debit cards or credit cards. Other fields of application are, for example, indications based on electronic ink such as price labels, information labels, product codes or identifiers.

A preferred application of pushbuttons according to the invention is in smart cards for use as a means of payment. These are thin cards that have a card body, generally made of plastic, and can contain a series of active and inactive input and output elements, data memories, as well as identification and transmission devices such as wireless network interfaces, RF-ID (Radio Frequency Identification) antennas or NFC (Near Field Communication) units, as well as present a secure element. The use of such active elements presupposes an autonomous energy supply in the form of thin accumulators for their operation. However, due to the limited dimensions of such smart cards, which are generally produced in credit card format, the storage capacity of these energy storage units is very limited. The reduced available space further leads to preferably using input elements which have a low space demand, with at the same time a large number of input possibilities and low energy demand. These properties are advantageously made available by means of a button according to the invention. Another advantage of using pushbuttons according to the invention on a smart card of this type is that they can also be used to turn the smart card on and off, so that it does not present power consumption when not in use. In this regard, it is particularly advantageous that the smart card cannot be read in the off state.

In a smart card made as described above it is possible to combine the function of a series of debit cards and credit cards by assigning a unique card number and a series of sequence numbers to the smart card. These sequence numbers can be used to identify a certain debit card or credit card. For this, the assignment of a certain debit card or credit card is stored in the data memory of the smart card and in a network data memory. In this way, by using one or more buttons according to the invention, it is possible for the user to select a certain debit card or credit card directly on the smart card for a payment. In a method for the development of the payment, the card number of the smart card and the sequence number assigned to the debit card or credit card selected in each case are transmitted to a service provider system. It can access the network memory and determine the assignment of the selected debit card or credit card to the respective sequence number of the smart card. Consequently, the payment process can then be carried out via the selected debit or credit card.

Advantageous configurations of the pushbutton according to the invention, as well as alternative embodiments are explained in more detail below by means of the figures.

Figure 1 shows a representation of a section through a button according to the invention.

Figure 2 shows a representation of a smart card with a button according to the invention.

Figure 3 shows a flow chart of a method for using a smart card according to Figure 2 to transmit payment information.

Figure 1 shows a vertical section through a button 1 according to the invention in a perspective view in a preferred embodiment variant. The pushbutton 1 consists of a first switch contact 2, a second switch contact 3 and a third switch contact 4, which are arranged parallel to each other and do not touch each other in a starting state of the pushbutton 1. The The second switching contact 3 is arranged between the first 2 and the third switching contacts 4. The switching contacts can be made in the preferred embodiment represented by flexible foils, metal foils, FP, PCBA etc. sides opposite the second switch contact 3 from the first 2 and the third switch contact 4 in an electrically conductive or non-conductive manner. If a user of the pushbutton 1 exerts a force on the first switch contact 2 or the third switch contact 4, the respective switch contact moves closer to the second switch contact 3 until it touches it and establishes an electrical connection in a metastable state through which current can flow. If the application of force ends, pushbutton 1 goes back to the starting state, and the line connection is separated. This arrangement according to the invention, represented in FIG. 1, of the switching contacts 2, 3 and 4 advantageously enables operation on both sides of the pushbutton 1 according to the invention.

In the preferred embodiment variant represented in figure 1, the pushbutton 1 has a thickening or elevation 5 in the center of the second switching contact 3. This reduces the distance from the second switching contact 3 to the first 2, or third switching contact 4. The advantage is thus obtained that the force required to operate the button 1 can be varied in a simple way. In alternative embodiments, this thickening or elevation 5 can be formed in different places on the side of the switch. second switching contact 3 associated with the first switching contact 2, or the third switching contact 4.

For the rest, in this way different distances can be implemented with respect to the first 2 and the third switching contact 4. It is therefore advantageously possible to provide the user with different haptic feedback for the operation of the first 2 or the third switching contact. switching 4.

The pushbutton 1 shown in FIG. 1 also has an evaluation unit 6 and an energy storage unit 7. The energy storage unit 7 provides an auxiliary voltage that enables the evaluation unit 6 to record pushbutton 1 touches on a capacitive or inductive base. In an alternative embodiment variant, the auxiliary voltage is made available by means of a power source, such as, for example, a charger.

The integration of the evaluation unit 6 in the pushbutton 1 according to the invention enables the pushbutton 1 to function as an inductive or capacitive touch sensor that can be operated on both sides, in addition to its properties as a mechanical pushbutton that can be operated on both sides. In this way, the advantage is obtained that additional input possibilities can be implemented with a single button 1. In alternative embodiments, only the first switching contact 2 or only the third switching contact 4 can be operated as a touch sensor.

The energy storage unit 7 shown in Fig. 1 can adopt both a ready-to-run state and a non-ready-to-run state. A change from the ready-for-operation state to the non-ready-for-operation state, or vice versa, can be made by simultaneously pressing the first 2 and the third switching contact 4. In this way a line connection is established between the first 2 , the second 3 and the third switching contact 4. This function enables the energy storage unit 7 to only make auxiliary voltage available if it is necessary to operate the pushbutton 1 as a capacitive or inductive touch sensor. In this way the advantage is achieved that a discharge of the energy storage unit 7 is avoided when the push button 1 is not in use. In alternative embodiments, the switch between the ready-for-operation state and the non-ready-for-operation state can also be implemented by pressing exclusively on the first 2 or the third switching contact 4, or any combination of these possibilities. . In the case of using the pushbutton according to the invention in electronic devices, this function can be used to prevent inadvertent switching on of the respective device and thus increase the ignition safety.

Figure 2 shows a perspective view of a smart card 8, containing a button 1 according to the invention according to Figure 1, with an evaluation unit 6 and an energy storage unit 7 associated. The smart card 8 additionally has a screen 9, a security element 10, an identification and transmission device 11, a data memory 12 and three input elements 13. The input elements 13 can also be designed as a button 1 according to the invention, or alternative embodiments such as mechanical buttons, inductive touch sensors or capacitive touch sensors or any combination thereof. The identification and transmission device 11 can be realized as an RFID antenna, as an NFC module or any other device for wireless or contact communication. The screen 9 can be made as a conventional LCD screen, electronic ink or similar screen. Otherwise, it may be sensitive to the touch. The energy storage unit 7 of the button 1 is used to supply the other components of the smart card 8 with power. Consequently, by means of the advantageous configuration of the pushbutton 1, it is possible, as described in figure 1, to switch the energy storage unit 7 to the state ready for operation, as well as to the state not ready for operation and consequently connect or disconnecting the entire smart card 8. The advantage is thus achieved that a discharge of the energy storage unit 7 is prevented when the smart card 8 is not in use. This also prevents a reading of the smart card 8. In another variant embodiment, several buttons 1 according to the invention can be used on a smart card 8. In this way, the power-on security can be further increased when it is necessary, for example, to operate several pushbuttons 1 simultaneously to switch the energy storage unit 7 to the ready-for-operation state. Otherwise, this can be used to call up certain safety functions by means of the combined operation of different buttons 1. Due to the particularly slim design of the buttons 1, it is possible, for example, that they are arranged side by side, top and bottom in an apparatus such as the smart card 8 described. In this way a particularly ergonomic design of the positions of the buttons 1 can be achieved. This opens the possibility of, for example, by placing the smart card 8 on a flat surface, to operate only one side of the buttons 1 either by contact or by means of the application of force or pressure.

In the preferred embodiment variant, the smart card 8 shown in FIG. 2 is assigned a card number by means of which the smart card 8 can be uniquely identified. This card number is then assigned a series of numbers. sequence. This results in the advantage that the smart card 8 is uniquely identifiable, and different operating modes of the smart card described below can be assigned to the sequence numbers.

The application of one or, in alternative embodiments, several buttons 1 according to the invention on the smart card 8 represented in FIG. 2 advantageously enables a series of different input possibilities. If the smart card 8 is placed on a flat surface, they can be pressed or touched independently, for example, the first 2 or the third switching contact 4 of the button 1 used in each case. This can be used, for example, to enter PIN codes or unlock codes that prevent unauthorized users from using the smart card 8.

Figure 3 shows a flow chart of a method for the use of a smart card 8 according to Figure 2 for the transmission of payment information. The identification and transmission device 11, of the smart card 8 represented in figure 2, is configured in a preferred embodiment variant to communicate with a card reader 12, or to be able to connect with it. A card reader 12 can be any sales terminal, a debit card or credit card reader, with which payment processes can be developed. This is configured to access a payment service system 13, which can access a network data memory 14. The identification and transmission device 11 transmits after the connection of the smart card 8 with the card reader 12 the number number and a sequence number to the card reader 12.

In this way the smart card 8 can be used to develop payment processes, this being able to combine the function of several debit cards and credit cards. To do this, a sequence of initialization stages is executed. These consist of assigning one of the sequence numbers of the card number of smart card 8 to a selected debit card or your debit card number, or to a credit card or your credit card number, and depositing this assignment in the data memory 12 of the smart card 8 and in the network data memory 14. The network data memory 14 is a memory that can be consulted through a data network such as, for example, the Internet. The allocation takes place by means of the connection of the smart card 8 with a computing unit 15, such as, for example, a smartphone, a tablet, a laptop or a desktop computer. By connecting to the smart card 8, the computing unit 15 gains access to the data memory 12 of the smart card 8. Otherwise, the computing unit 15 has access to the data network, and consequently to the memory of network data 14. The computing unit 15 executes a processing program that allows the user of the smart card 8 to perform the assignment, the processing program storing it in the data memory 12 of the smart card 8 and in the data memory of the network 14.

Only a connection from the smart card 8 to the computing unit 15 is required to execute the initialization steps. If these have taken place, the smart card 8 can autonomously transmit payment information. To this end, the user of the smart card 8 directly selects by means of the smart card 8 a debit card or credit card previously initialized within the framework of the initialization steps. The identification and transmission device 11 then transmits the card number of the smart card 8 and the sequence number previously assigned to the selected debit card or credit card to the card reader 1. This transmits the card number and the sequence number to the payment service provider system 13. The payment service provider system 13 accesses the network data memory 14 to query the assignment of the sequence number to the debit card or credit card selected by the user . In this way, the payment service provider system 13 receives information about which account associated with the credit card debit or credit card must be charged with the payment transaction.

In an alternative embodiment variant, in the case of selection of a debit card to carry out the payment process by the user, the debit card number of the selected debit card is transmitted directly to the card reader 12 to via the smart card 8. The debit card is then directly identified by means of the secure element 10 via the card reader 12.

This method offers the advantage that the smart card 8 can thus take over the function of several debit cards and credit cards.

Claims (10)

1 Pushbutton (1), comprising a first switching contact (2) and a second switching contact (3), which are arranged spaced apart and in parallel with each other, the first switching contact being configured (2) to approach the second switch contact (3) with application of force until it touches it and establish a power line connection with the second switch contact (3), the pushbutton (1) comprising a third switch contact ( 4), which is arranged spaced from the second switch contact (3) and in parallel on a side opposite the first switch contact (2), characterized in that the third switch contact (4) is configured to approach the second switching contact (3) with application of force until it touches it and establishing a power line connection with the second switching contact (3), and the pushbutton (1) comprises an evaluation unit (6), which is c onfigured to operate the first (2) and / or the third switching contact (4) additionally as a capacitive or inductive touch sensor. 2 Pushbutton (1) according to claim 1, characterized in that the pushbutton (1) comprises an energy storage unit (7) that can adopt a ready-to-operate state, in which the energy storage unit (7) supplies the evaluation unit (6) with voltage, and a state not ready for operation. 3 Pushbutton (1) according to claim 2, characterized in that an application of force both on the first switching contact (2) and on the third switching contact (4) establishes a line connection between the first (2), the second (3) and third switching contact (4), and switches the energy storage unit (7) from the not ready for operation state to the ready for operation state or from the ready for operation state to the not ready for operation state. the performance. 4 Pushbutton (1) according to claim 2, characterized in that an application of force on the first switching contact (2) or on the third switching contact (4) passes the energy storage unit (7) from the not ready state for operation to the ready-to-run state, or from the ready-to-run state to the not-ready state. 5 Pushbutton (1) according to one of Claims 1 to 4, characterized in that the second switching contact (3) has a thickening or elevation (5) that reduces a distance from the second switching contact (3) to the first ( 2) and / or the third switching contact (4). 6 Pushbutton (1) according to one of Claims 1 to 4, characterized in that the distances of the first switching contact (2) from the second switching contact (3) and of the third switching contact (4) from the second changeover contact (3) are of different magnitudes. Smart card (8), comprising at least one button (1) according to one of Claims 2 to 6, characterized in that the smart card (8) is assigned a card number and a plurality of sequence numbers. 8 Smart card (8) according to claim 7, characterized in that the smart card (8) further comprises an identification and transmission device (11), a security element (10), a data memory (12), a screen (9), an inductive touch sensor, as well as a capacitive touch sensor, being able to connect the identification and transmission device (11) with a card reader (12), which is configured to access a payment service provider system ( 13), which is configured to access a network data memory (14). Use of a smart card (8) according to claim 8 for the transmission of payment information, comprising: the initialization stages: - assign in each case a sequence number from the card number of the smart card (8) to a credit card number or debit card number, and - storing this assignment in the data memory (12) of the smart card (8) and in the network data memory (14) that can be consulted through a data network; and the stages of operation: - select a credit card number or a debit card number by the user of the smart card (8) by means of the smart card (8), - transmitting by means of the identification and transmission device (11) the card number of the smart card (8) and the sequence number associated with the selected debit card number or credit card number to the card reader (12), - transmitting by means of the card reader (12) the card number of the smart card (8) and the sequence number to the payment service provider system (13), and - consulting the credit card number or debit card number assigned to the sequence number transmitted by the payment service provider system (13) in the network data memory (14). Use of a smart card (8) according to claim 9, characterized in that the assignment of the sequence number of the card number of the smart card (8) takes place by connecting the smart card (8) to a computing unit (15 ), which has access to the data memory (12) of the smart card (8) and to the network data memory (14), and is configured to execute a management program that passes through the initialization steps according to claim 9.